A method is described that involves tracking a fringe line disturbance that has breached its field of reference. The method also involves translating each pixel location of the tracked fringe line disturbance to an x,y,zs data point. x and y represent a position on the plane of an interferometer's sample stage. zs represents the height of a sample above the x,y position. The sample is placed upon the sample stage of an inteferometer so as to create the fringe line disturbance. The fringe line disturbance is observed on the interferometer's detector.
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1. A method, comprising:
tracking a fringe line disturbance that has breached its field of reference on a reference field by reference field basis by:
reading image data for a first reference field, said image data comprising pixel locations of one or more detected fringe lines within said first reference field, said fringe line disturbance's fringe line being one of said one or more detected fringe lines;
starting at a pixel location that corresponds to an intercept of said fringe line with a border of said first reference field, following each pixel location of said fringe line in a direction away from said border;
reading image data for a second reference field, said image data for said second reference field comprising pixel locations of one or more detected fringe lines within said second reference field, said fringe line being one of said one or more detected fringe lines within said second reference field, said second reference field adjacent to said first reference field;
starting at a pixel location that corresponds to an intercept of said fringe line with a border of said second reference field, following each pixel location of said fringe line in a direction away from said border of said second reference field;
translating each pixel location of said tracked fringe line disturbance being followed to an x,y,zs data point, where x and y represent a position on the plane of an interferometer's sample stage, and where zs represents the height of a sample above said x,y position, said sample placed upon the sample stage of an inteferometer so as to create said fringe line disturbance, said fringe line disturbance observed on said interferometer's detector.
10. A machine readable medium comprising instructions which when executed by a processor cause said processor to perform a method, comprising:
tracking a fringe line disturbance that has breached its field of reference on a reference field by reference field basis by:
reading image data for a first reference field, said image data comprising pixel locations of one or more detected fringe lines within said first reference field, said fringe line disturbance's fringe line being one of said one or more detected fringe lines;
starting at a pixel location that corresponds to an intercept of said fringe line with a border of said first reference field, following each pixel location of said fringe line in a direction away from said border;
reading image data for a second reference field, said image data for said second reference field comprising pixel locations of one or more detected fringe lines within said second reference field, said fringe line being one of said one or more detected fringe lines within said second reference field, said second reference field adjacent to said first reference field;
starting at a pixel location that corresponds to an intercept of said fringe line with a border of said second reference field, following each pixel location of said fringe line in a direction away from said border of said second reference field;
translating each pixel location of said tracked fringe line disturbance being followed to an x,y,zs data point, where x and y represent a position on the plane of an interferometer's sample stage, and where zs represents the height of a sample above said x,y position, said sample placed upon the sample stage of an inteferometer so as to create said fringe line disturbance, said fringe line disturbance observed on said interferometer's detector.
2. The method of
3. The method of
line-formulae description="In-line Formulae" end="lead"?>zs=REF2+(R−dz) line-formulae description="In-line Formulae" end="tail"?> where:
a) REF2 is a baseline reference that takes into account how many reference fields said fringe line has already breached;
b) R is a parameter that indicates the amount of sample height per reference field breach; and
c) dz is the difference between said pixel's z axis location on said detector and the location of the lower border of said reference field factored by a per pixel unit of sample height parameter.
4. The method of
5. The method of
6. The method of
7. The method of
line-formulae description="In-line Formulae" end="lead"?>zs=REF2−dz line-formulae description="In-line Formulae" end="tail"?> where:
a) REF2 is a baseline reference that takes into account how many reference fields said fringe line has already breached; and
b) dz is the difference between said pixel's z axis location on said detector and the location of the lower border of said reference field factored by a per pixel unit of sample height parameter.
8. The method of
9. The method of
11. The method of
12. The method of
line-formulae description="In-line Formulae" end="lead"?>zs=REF2+(R−dz) line-formulae description="In-line Formulae" end="tail"?> where:
a) REF2 is a baseline reference that takes into account how many reference fields said fringe line has already breached;
b) R is a parameter that indicates the amount of sample height per reference field breach; and
c) dz is the difference between said pixel's z axis location on said detector and the location of the lower border of said reference field factored by a per pixel unit of sample height parameter.
13. The method of
14. The method of
15. The method of
16. The method of
line-formulae description="In-line Formulae" end="lead"?>zs=REF2−dz line-formulae description="In-line Formulae" end="tail"?> where:
a) REF2 is a baseline reference that takes into account how many reference fields said fringe line has already breached; and
b) dz is the difference between said pixel's z axis location on said detector and the location of the lower border of said reference field factored by a per pixel unit of sample height parameter.
17. The method of
18. The method of
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The field of invention relates generally to measurement techniques; and, more specifically, to a pre-established reference scale for an interferometric topological measurement.
1.0 Basic Interferometry
Interferometry involves the analysis of interfering waves in order to measure a distance. Interferometers, which are measurement tools that perform interferometry, typically reflect a first series of optical waves from a first reflecting surface; and, reflect a second series of optical waves from a second reflecting surface. The first and second series of waves are subsequently combined to form a combined waveform. A signal produced through the detection of the combined waveform is then processed to understand the relative positioning of the reflective surfaces.
Referring to
At least a portion of the light that is directed to the plane mirror 103 reflects back to the splitter 102 (by traveling in the +z direction after reflection); and, at least a portion of the light that is directed to the reference mirror 104 reflects back to the splitter 102 (by traveling in the −y direction after reflection). The reflected light from the reference mirror 104 and plane mirror 103 are effectively combined by the splitter 102 to form a third group of light waves that propagate in the −y direction and impinge upon a detector 105. The optical intensity pattern(s) observed by the detector 105 are then analyzed in order to measure the difference between the distances d1, d2 that exist between the plane mirror 103 and the reference mirror 104, respectively.
That is, for planar wavefronts, if distance d2 is known, distance d1 can be measured by measuring the intensity of the light received at the detector 105. Here, according to wave interference principles, if distance d1 is equal to distance d2; then, the reflected waveforms will constructively interfere with one another when combined by the splitter 102 (so that their amplitudes are added together). Likewise, if the difference between distance d1 and distance d2 is one half the wavelength of the light emitted by light source 101; then, the reflected waveforms will destructively interfere with one another when combined by the splitter 102 (so that their amplitudes are subtracted from one another).
The former situation (constructive interference) produces a relative maximum optical intensity (i.e., a relative “brightest” light) at the detector 105; and, the later situation (destructive interference) produces a relative minimum optical intensity (i.e., a relative “darkest” light). When the difference between distance d1 and distance d2 is somewhere between zero and one half the wavelength of the light emitted by the light source 101, the intensity of the light that is observed by the detector 105 is less than the relative brightest light from constructive interference but greater than the relative darkest light from destructive interference (e.g., a shade of “gray” between the relative “brightest” and “darkest” light intensities). The precise “shade of gray” observed by the detector 105 is a function of the difference between distance d1 and distance d2.
In particular, the light observed by the detector 105 becomes darker as the difference between distance d1 and distance d2 depart from zero and approach one half the wavelength of the light emitted by the light source 101. Thus, the difference between d1 and d2 can be accurately measured by analyzing the optical intensity observed by the detector 105. For planar optical wavefronts, the optical intensity should be “constant” over the surface of the detector 105 because (according to a simplistic perspective) whatever the difference between distance d1 and d2 (even if zero), an identical “effect” will apply to each optical path length experienced by any pair of reflected rays that are combined by the splitter 102 to form an optical ray that is directed to the detector 105.
Here, note that the 45° orientation of the splitter 102 causes the reference mirror directed and plane mirror directed portions of light to travel equal distances within the splitter 102. For example, analysis of
2.0 Interferometer Having a “Tilted” Reference Mirror
Referring to
Here, as wave interference principles will still apply at the detector 205, the variation in optical path length that is introduced by the tilted reference mirror 204 can be viewed as causing optical path length differences experienced by light that impinges upon the detector 202 to effectively progress through distances of λ/2, λ, 3λ/2, 2λ, 5λ/2, 3λ, etc. (where A is the wavelength of the light source). This, in turn, corresponds to continuous back and forth transitioning between constructive interference and destructive interference along the z axis of the detector 205.
Here, notice that the optical intensity pattern 350 includes relative minima 352a, 352b, and 352c; and, relative maxima 351a, 351b, 351c, and 351d. The relative minima 352a, 352b, and 352c, which should appear as a “darkest” hue within their region of the detector 305, are referred to as “fringe lines”.
The present invention is illustrated by way of example and not limitation in the figures of the accompanying drawings.
As described below, principles of interferometry are utilized so that an accurate description of the surface topology of a sample can be gained. More specifically, fringe line disturbances observed on the detector of an interferometer (that are caused by the introduction of the sample to the interferometer) are measured against a pre-established reference scale. As a result, the height of the sample can be mapped to specific locations on the surface of the sample; which, in turn, allows for the development of a precise description of the topographical nuances of the sample.
1.0 Mapping of Detector Surface Location to Sample Stage Surface Trace
Referring to
2.0 Interferometry Measurement Technique Employing a Pre-Established Measurement Scale
Better said, the disturbances experienced by the fringe lines in response to the sample being introduced to the interferometer can be precisely translated into sample height along known locations in the xy plane of the sample stage. The pre-establishment of a reference scale not only allows for highly precise surface topography descriptions but also allows for efficiently produced surface topography descriptions (e.g., in terms of equipment sophistication and/or time expended).
3.0 Establishment of Measurement Scale
According to the methodology of
Here, an array of optically sensitive devices (e.g., an array of charge coupled devices (CCDs)) may be used to implement the detector 405. Each array location may be referred to as a “pixel”. Because of the array, each optically sensitive device that a disturbed fringe line feature runs across will correspond to a unique x,y,z position (above the surface plane of the detector 405) along the topography of the sample. Better said, the setting of the accuracy in the xy plane 610 allows a detector pixel to be “mapped” to a specific position in the xy plane of the sample stage. As such, should a fringe line become disturbed upon introduction of a sample to the interferometer, the distance(s) that the fringe line moves upon the detector from its original, undisturbed pixel locations will correspond to the height of the sample at those particular x,y sample stage positions that the original, undisturbed pixel locations mapped to.
Thus, as each of the optically sensitive devices that make up the array consume a quantifiable amount of surface area on the plane of the detector 405 (i.e., each pixel has a “size”), when measuring the expanse of a fringe line disturbance, each pixel will typically correspond to a particular unit of “height” above the sample stage as measured along the z axis of the detector. Better said, recalling from the discussion of
Here, the height of the sample can be deduced from the distance along the z axis that a fringe line section or portion will “move” along the surface of the detector 405 (i.e., be disturbed) by the introduction of the sample 460 to the interferometer. As such, each pixel position can be correlated to a specific unit distance along the z axis above the surface of the sample stage 403; which, in turn, can be used to “figure out” the height of the sample above the sample stage 403. More discussion of this topic is provided further below with respect to
For purpose of explaining
Once the fringe lines have been aligned 610 to a calibration standard and the per pixel unit of sample height measurement is calculated 611, a pre-established measurement scale can be formed by recording 612: 1) information related to the mapping of the detector's fringe lines to the sample stage 403 without a sample being placed on the sample stage (e.g, for each fringe line observed on the detector 405 when a sample is not placed upon the sample stage: a) recording its x,z pixel locations on the detector 405; and b) recognizing how the x,z locations on the detector 405 map to x,y locations upon the sample stage 403); and, 2) the per pixel unit of sample height measurement.
Note that a sample is the “thing” whose surface topography is to be measured. According to the methodology of
3.1 Aligning Fringe Lines with a Calibration Standard
Note that, in the exemplary depiction of
As fringe spacing is a function of the tilt angle θ, the fringe line spacing can be made to be equidistant with the calibration marking spacings by adjusting 820 the tilt angle θ as appropriate. Depiction 801a shows an embodiment where neighboring fringe line spacings are made equidistant with neighboring calibration marking spacings. As such, neighboring calibration markings 810a through 810e having the same spacing (“Y”) as neighboring fringe lines 811a through 811e. In other embodiments (e.g., where the density of fringe lines is greater than the density of calibration markings), a fixed number of fringe lines may be set per calibration marking. For example, as just one embodiment, 10 fringe lines may be established per calibration marking allowing for a fringe line density that is 10 times that of the calibration marking density of the calibration standard.
Note, however, that even though the depiction 801a of
Here, in conjunction with the mapping of the fringe lines to traces that run along the x axis of the sample stage 403 at specific y axis locations (as discussed in detail previously with respect to
In an embodiment, the understood distance between neighboring fringe lines as they map to the xy plane of the sample stage is normalized by the number of pixels between neighboring fringe lines as observed on the detector. This calculation effectively corresponds to a distance along the y axis of the sample stage (and along the x axis of the sample stage) that each pixel corresponds to (i.e., a distance “per pixel” along both the x axis and the y axis of the detector that each pixel represents).
For example, if 10 pixels exist between neighboring fringe lines on the detector; and, if neighboring fringe lines are understood to map to sample stage traces that are spaced a distance of Y apart as a result of the calibration process—then, a per pixel resolution of 0.1Y in both the x and y directions may be said to exist. In this case, for example, a string of 5 consecutive pixels along the x axis of the detector can be recognized as mapping to a distance of 0.5Y over the surface of the sample stage (or sample); and, likewise, a string of 5 consecutive pixels along the z axis of the detector can be recognized as mapping to a distance of 0.5Y over the surface of the sample stage (or sample).
Here, recalling that a pre-established measurement scale can be partially formed by recording information related to the mapping of the detector's fringe lines to the sample stage, note that storing this per pixel resolution in the x and y direction qualifies as storing information that can be used toward this objective. For example, if the per pixel resolution in the x and y direction corresponds to a distance of 0.1Y; then, undisturbed fringe lines detected to be 30 pixels apart along the z axis of the detector can be recognized as representing traces spaced a distance of 3Y apart along the y axis of the sample stage. Similarly, if fringe lines extend 100 pixels across the x axis of the detector; then, these same fringe lines may be recognized as traces that run over a distance of 10Y along the x axis of the sample.
Lastly, note that distinction should be drawn between the previously discussed “per pixel unit of sample height measurement” (and, which is discussed in more detail immediately below) and the just discussed “per pixel” distance along the x and y axis of the sample stage. Better said, according to the present measurement technique, pixel locations can be used not only to identify a specific position in the xy plane of the sample stage but also to identify sample height along the z axis above the sample stage. The “per pixel” distance along the x and y axis of the sample stage is devoted to the former; while, the “per pixel unit of sample height measurement” is devoted to the later.
3.2 Calculation of Per Pixel Unit of Sample Height Measurement
Referring back to
This shortened optical path length corresponds to change in optical path length difference; which, in turn, causes a disturbance to the position of a fringe line. Thus, in order to calculate the per pixel unit of sample height measurement, the amount of disturbance in the positioning of a fringe line should be correlated to the change in optical path length that occurs when a sample is placed on the sample stage. Here, in order to better comprehend the change in optical path length, an analysis of an interferometer without a sample is in order; and, an analysis of an interferometer with a sample is in order.
Referring now to
This property can be viewed “as if” there is a relationship between: 1) the “intercepts” on the tilted reference mirror 404 of each integer spacing of λ/2 between the tilted reference mirror 404 and the θ=0° reference plane 499; and, 2) the location of the fringe lines on the detector itself 405. Better said, recalling from the discussion of
Here, as ˜λ/θ is consistent with λ/(2 sin θ) (particularly for a small angle of θ), a correlated relationship can therefore be envisioned between the: 1) the spacing between the intercepts upon the tilted reference mirror 404 of each integer λ/2 spacing between the tilted reference mirror 404 and the θ=0° reference plane 499; and, 2) the spacing between the fringe lines that appear on the detector 405.
Like
Thus, the “variation” in path length from the splitter 902a to the tilted reference mirror 904a can be viewed as the “primary contributor” to the “variation” in optical path length difference that occurs between light directed to the sample stage 903a and light directed to the tilted reference mirror 904a; which, in turn, causes the appearance of multiple fringe lines on the detector 905a. Here, as the “variation” in path length from the splitter 902a to the tilted reference mirror 904a clearly occurs within the region between the θ=0° reference plane 999a and the tilted reference mirror 904a, the region between the θ=0° reference plane 999a and the tilted reference mirror 904a serves as a primary region on which to focus the optical analysis.
Recall that, without a sample being placed on the sample stage 903a, a fringe line appears for every integer spacing of λ/2 between the tilted reference mirror 904a and the θ=0° reference plane 999a; and that, a correlating relationship can be envisioned between the spacing of the fringe lines on the detector and the intercept spacings on the tilted reference mirror 404. As such,
Referring to
The change in optical path length causes a disturbance to the position of the fringe line 995a because the optical path length difference (as between light directed to the sample stage and light directed to the reference mirror) has been changed by the introduction of the sample. As such, fringe line 995a moves down along the detector 905b to a new position (as observed in
Here, a change of λ/4 drops the fringe line 995b halfway between its original position 907 (before introduction of the sample 912) and fringe line 996b. This arises naturally when one considers that spacing 993b can be broken down into a first segment that is 3λ/4 in length and a second segment that is λ/4 in length (noting that a total length of λ for spacing 993b is preserved). The λ/4 segment helps form a right triangle (observed in
Consistent with the analysis provided just above, note that a sample 912 height of λ/2 would have caused fringe line 995b to drop far enough so as to completely overlap fringe line 996b. As such, it is apparent that the “per pixel unit of sample height measurement” can be calculated as λ/(2N) where N is the number of pixels between neighboring fringe lines on the CCD detector 905a when a sample is not placed on the sample stage 904a (as observed in
Referring then back to
In an embodiment, once the “per pixel unit of sample height measurement” is calculated 611, information related to the mapping of the detector's fringe lines to the sample stage is stored 612 along with the “per pixel unit of sample height measurement”; which, as already discussed above, corresponds to the storage of information that can be used to effectively construct a measurement scale against which fringe line changes can be measured to determine the topography of a sample.
4.0 Embodiment of Apparatus
In order to properly direct light as described above, the splitter 1002 is positioned at an angle α with respect to a plane where a surface topology measurement is made (e.g., the xy plane as seen in FIG. 10A). In a further embodiment, α=45°; but those of ordinary skill will be able to determine and implement a different angle as appropriate for their particular application. The splitter 1002 may also be designed to direct 50% of the light from the light from the light source 1001 toward the reference mirror 1004 and another 50% of the light from the light from the light source 1001 toward the sample stage 1003. But, those of ordinary skill will be able to determine other workable percentages.
In a broader sense, the reference mirror 1004 may be viewed as an embodiment of a reflecting plane that reflects light back to the splitter 1002. A reflecting plane may be implemented with a number of different elements such as any suitable reflective coating formed over a planar surface. The reflecting plane may be tilted at an angle θ so that suitably spaced fringe lines appear along the surface of a detector 1005. As discussed, the positioning of θ can be adjusted in order to align the fringe lines to a calibration standard.
The sample stage 1003 supports the test sample whose surface topography is to be measured. After light is reflected from the sample stage 1003 and/or a sample placed on the sample stage 1003, it is combined with light reflected from the reference mirror 1004. The combined light is then directed to detector 1005. In a broader sense, the detector 1005 may be viewed as an opto-electronic converter that converts the optical intensity pattern at the detector surface into an electric representation. For example, as discussed previously, the detector 1005 can be implemented as a charge coupled device (CCD) array that is divided into a plurality of pixels over the surface where light is received. Here, an output signal is provided for each pixel that is representative of the intensity received at the pixel.
A fringe detection unit 1006 processes the data that is generated by the detector 1005. The fringe detection unit 1006 is responsible for detecting the position(s) of the various fringes that appear on the detector 1005. An embodiment of a fringe detection unit 1006 is described in more detail below with respect to
The optical intensity values from a column of CCD data should indicate a series of relative minima. That is, as each column of CCD data corresponds to a “string” of optical intensity values that impinge the CCD detector along the z axis and at the same x axis location, if the optical intensity values are plotted with respect to their z axis location, a collection of relative minimum points should appear. This follows naturally when one refers, for example, back to FIG. 3 and recognizes that by traveling along the optical intensity pattern 350 in the +z direction at a fixed x coordinate a series of relative minima will be revealed (e.g., at locations that correspond to fringe lines 352a, 352b, 352c). Another example is provided in
From the depiction of
Taking the first derivative 1104 of a column of CCD data (with respect to the z axis) and then determining 1105 where the first derivative changes from a negative polarity to a positive polarity is a way to identify the z coordinate for each pixel that receives a fringe line for a particular column of CCD data. Although such an approach could be done in software, hardware or a combination of the two,
The comparator 1109 indicates which of the pair of waveforms 1112, 1113 is greater. Waveform 1114 provides an example of the comparator output 1109 signal that is generated in response to waveforms 1112, 1113. Note that a rising edge is triggered for each relative minima (e.g., at points z2, z4, z6, z8, etc.). One of ordinary skill will recognize that indicating which of the pair of waveforms 1112, 1113 is greater mathematically corresponds to taking the first derivative 1105 of waveform 1112 and determining its polarity. Here, determining where the polarity changes from negative to positive corresponds to identifying a relative minimum (because the slope of a waveform changes from negative to positive at a relative minimum). As such, as seen in
4.0 Embodiment of a Pre-Established Measurement Scale and a Topography Measurement Based Thereon
Referring back to
Referring back to
From the discussion of fringe line detection (as performed by the fringe detection unit 1006) provided just above with respect to
Recall from
In an embodiment where each fringe line maps to a trace that runs along the x axis of the sample and that is spaced Y apart from the trace of a neighboring fringe line on the sample stage, trace 1204 will correspond to a y axis location on the sample of y=−Y and trace 1202 will correspond to a y axis location on the sample of y=+Y. Similarly, trace 1205 will correspond to a y axis location on the sample of y=−2Y and trace 1201 will correspond to a y axis location on the sample of y=+2Y. Note that, briefly referring back to
Keeping track of the location of each fringe line on the detector (e.g., the (x,z) pixel coordinate of each pixel having an “X” in
Note that keeping track of the fringe detection locations corresponds to a degree of data compression because pixel coordinates that are not associated with a fringe line (i.e., those not having an “X” in
As described above with respect to
Each profile 1401 through 1405 corresponds to an accurate description of the sample's topography at the y axis locations that are defined by the measurement scale. Note that topography profiles 1401 through 1405 are measured vertically in terms of pixels; and, as a result, the “per pixel unit of sample height measurement” parameter can be used to precisely define the sample's height at each x axis location. For example, note that the trapezoid profile reaches a maximum height of 3 pixels. Here, if the “per pixel unit of sample height measurement” parameter corresponds to 1 nm per pixel, the sample will have a measured maximum height of 3 nm.
While
The fringe line extraction unit 1501 extracts corresponding fringe lines for comparison from their appropriate memory regions 1523, 1524. Here, corresponding pairs of fringe lines may be extracted in light of the manner in which they were stored. For example, if the z axis pixel coordinates for a first fringe line associated with the measurement scale information (e.g., fringe line 1201 of
The sample stage y axis location for these fringe lines may be kept track of (e.g., by being stored along with the pixel locations of each undisturbed fringe line in memory 1524) so that the analysis of the pair of fringe lines that are together presented at inputs 1522, 1521 can be traced to a specific sample stage y axis location. Once a pair of corresponding fringe lines have been extracted, the differences between the disturbed and disturbed locations are calculated and then multiplied by −1 to properly invert the data (note that the factor of −1 may be removed if the reference mirror tilt angle is pivoted at the bottom of the reference mirror rather than the top (as observed throughout the present description)).
This creates a new string of data that represents the sample profile (as measured in pixels) at the y axis location of the sample stage that the pairs of fringe lines correspond to (e.g., profile 1402 of FIG. 14). As such, multiplication of the pixel count at each x axis coordinate by the “per pixel unit of sample height measurement” parameter should produce the correct sample profile from the pair of fringe lines. Beyond the topography measurement unit, the topography profiles may be stored or displayed. They may also be compressed through various data compression techniques to reduce the amount of data to be handled.
Referring back to
As such, whether or not (or to what degree) data processing is performed through the execution of a software routine and/or dedicated hardware, the processing that is performed “behind” the detector may be viewed, more generically, as being performed by a “data processing unit” 1020. Here, the data processing 1020 unit may be implemented as dedicated hardware (e.g., as suggested by FIG. 10A); or, alternatively or in combination, may be implemented with a computing system. An embodiment of a computing system is shown in FIG. 10B. General purpose processors, digital signal processors (DSPs) and/or general purpose/digital signal hybrid processors may be employed as appropriate as well.
Thus, any of the signal processing techniques described herein may be stored upon a machine readable medium in the form of executable instructions. As such, it is also to be understood that embodiments of this invention may be used as or to support a software program executed upon some form of processing core (such as the Central Processing Unit (CPU) of a computer) or otherwise implemented or realized upon or within a machine readable medium. A machine readable medium includes any mechanism for storing or transmitting information in a form readable by a machine (e.g., a computer). For example, a machine readable medium includes read only memory (ROM); random access memory (RAM); magnetic disk storage media; optical storage media; flash memory devices; electrical, optical, acoustical or other form of propagated signals (e.g., carrier waves, infrared signals, digital signals, etc.); etc.
In other embodiments, the topography measurement unit 1006 may be implemented with dedicated hardware (e.g., one or more semiconductor chips) rather than a software program. In other embodiments, some combination of dedicated hardware and software may be used to develop the topography profiles. Further still, multiple topography profiles may be analyzed in parallel (e.g., with multiple implementations of the circuitry of
5.0 High Resolution Topographical Description Through Interleaving of Multiple Topographical Measurements
For example, if the sample stage were moved along the y axis by an amount Y/2, the tracings of the fringe lines would effectively “move” so as to trace over new locations of the sample.
It is important to note that other approaches can be used to effectively achieve the same or similar effect as described just above. That is, other optical techniques may be employed in order to effectively provide collections of tracings that can be interleaved together so as to form a higher resolution image of the overall sample. For example, according to one approach, the phase of the light emanating from the light source is adjusted in order to “adjust” the positioning of the fringe lines on the detector. Here, the activity of altering the phase of the light will have a similar effect to that of moving the sample stage as discussed above with respect to
That is, a new relative positioning of the mapping of the fringe lines traces over the sample will arise; which, in turn, creates a “new” set of tracings that can be interleaved with other sets of tracings (formed at different sample stage and/or light phase positionings) so as to form high resolution topography images. According to another related approach, the position of the tilted reference mirror is moved along the optical path axis (e.g., along the y axis as depicted in
Again, a new relative positioning of the mapping of the fringe lines traces over the sample will arise; which, in turn, creates a “new” set of tracings that can be interleaved with other sets of tracings. Further still, different light wavelengths may be employed (e.g., different “colors” of light may be used). Here, however, a separate measurement scale should be established for each wavelength of light that is employed.
Regardless as to whether or not or which technique (or combination of techniques) is used to create different sets of interleavable tracings, a word about magnification and the fringe lines is also in order. With respect to magnification, referring back to
With respect to fringe lines, note also that (as discussed) the fringe lines observed in
6.0 Characterization of Sample Composition Through Analysis of Fringe Line Intensity Information
More specifically, the material(s) from which the surface(s) of the sample are comprised may be determined by characterizing the reflectivity of the sample surface as a function of the optical wavelength of the interferometer's lightsource. The solid lined graphical component of
Better said, different materials or substances tend to exhibit different “reflectivity vs. wavelength” curves; and, as such, by developing a sample's “reflectivity vs. wavelength” curve, the material or substance from which it (the sample) is comprised can be determined. Here, rather than disposing the optical intensity values observed at the detector, they may be analyzed so as to determine a particular reflectivity of the sample for a particular wavelength of the interferometer's optical source.
By changing the optical source's wavelength; and, by monitoring the change in reflectivity of the sample in response thereto, a “reflectivity vs. wavelength” curve can be measured for the sample. This, in turn, can be used to determine the material composition(s) of the sample itself.
In various embodiments, optical intensities observed at the pixel locations where fringe lines are detected are used to perform the reflectivity analysis. Thus, in some cases, not only are the pixel locations of detected fringe lines employed (to develop the surface topography description of the sample); but also, the optical intensity values of the same fringe lines are used to help characterize the material(s) from which the sample is comprised.
However note also that, seizing upon the notion that a fringe line may be construed where appropriate so as to correspond to something other than a relative minimum, it some cases it may useful to track relative maximum optical intensity values rather than relative minimum optical intensity values for the sake of performing a reflectivity analysis. Thus, in some cases, a fringe line used for topography purposes may be the same fringe line used for reflectivity analysis (e.g., both are relative minimum); while, in other cases a fringe line used for topography purposes may be different from a fringe line used for reflectivity analysis (e.g., one is a relative minimum while another is a relative maximum).
Also, in further embodiments, interferometer characteristics that are spatially and/or wavelength dependent may be characterized beforehand so that any resulting detrimental affect(s) upon a reflectivity measurement can be successfully canceled out. For example, if a first pixel location is known to observe less light intensity than a second pixel location (e.g., on account of optical imperfections associated with the interferometer), those of ordinary skill will be able separate optical intensity differences (as between the pair of pixels) that are attributed to the interferometer's imperfections from those that are attributable to the sample's own characteristic reflectivity properties. The same may be said for an interferometer's wavelength related inconsistencies or imperfections (if any).
In a simplest case, the methodology of which is observed in
In a more likely scenario, which is elaborated upon in
That is, a first “reflectivity vs. wavelength” curve can be measured for the portion of the sample that maps to a first pixel location; and, a second “reflectivity vs. wavelength” curve can be measured for the portion of the sample that maps to a second pixel location. By keeping track of separate curves for different pixels (or perhaps different groups of pixels), should the sample have different materials/substances at the mapped to locations, different “reflectivity vs. wavelength” curves will reveal themselves as between the different pixel locations. As such, different materials/substances can be identified at precise sample locations.
Fringe lines may be re-positioned 1822, for example, by adjusting the tilt angle of the reference mirror so as to compensate for the movement that was caused by the change in wavelength. As such, a “new” data point for a “reflectivity vs. wavelength” curve can be generated by: 1) changing 1821 the wavelength of the lightsource; 2) adjusting 1822 the fringe lines so as to overlap with their position(s) that existed prior to the wavelength change; and 3) calculating and storing reflectivity at the fringe lines (or at least storing the observed intensity so that intensity can be later calculated) 1820. Note that reflectivity calculations can be readily made by those of ordinary skill because those of ordinary skill recognize that observed intensity is proportional to the reflectivity of the sample.
Note that, similar to the technique discussed previously with respect to
The corresponding groups of reflectivity curves may then be interleaved (e.g., akin to the concept discussed with respect to
Also, referring briefly back to
7.0 Signal Processing Techniques for Measuring Fringe Line Disturbances That Extend Outside Their Associated Reference Fields
Referring back to
Comparing
Thus, in general, according to various embodiments, a pre-defined maximum, measurable/allowable sample height may be recognized such that fringe line disturbances are designed to be kept within their corresponding field of reference. This keeps the signal processing needed for deriving topographical information nearer a minimum degree of sophistication. Note that any such “maximum height” configuration can be easily established through manipulation of fringe line spacing (e.g., adjustment of tilt angle θ). Furthermore, measurement resolution is not lost because interleaving techniques (e.g., as discussed with respect to
By contrast, however, should it be desirable to readily measure fringe line disturbances that breach their respective reference fields, more robust signal processing techniques may be used to accurately “track” a particular fringe line. That is, for example, if memory resources are again partitioned so as to organize the storing of data according to the image's reference fields, the pixel locations of different fringe lines may reside within a common reference field.
7.1 Memory Partitioning on a Reference Field-by-Reference Field Basis
Before commencing a discussion of more sophisticated signal processing techniques suitable for tracking multiple fringe lines within the same reference field, a brief discussion as to how memory resources used to store the pixel data of detected fringe line disturbances (e.g., such as memory 1023, 1523 of
Analyzing stored image data on a reference field by reference field basis allows for easy/efficient memory management. That is, the memory resources used to store the disturbed image data (e.g., memory resource 1023 of
For example, according to one embodiment, the storage of the reference scale information includes the storage (e.g., into memory resource 1024 of
As such, the borders of the reference fields (i.e., the locations of neighboring, undisturbed fringe lines) are always stored in previously defined memory/register locations—regardless if the borders themselves change from reference scale to reference scale. That is, for example, the first reference field can always be recognized as being bounded by the z axis values z1 and z2 that have been stored between the first and second pre-established memory locations of memory 1024—even if the test equipment stores different measurement scale embodiments (e.g., different fringe line spacings) over the course of its useful life.
As a consequence, the pixel locations of the detected fringe line disturbances can be easily “binned” according to their particular reference field. Better said, with knowledge of the reference field borders, the fringe detection unit 1006 can store fringe line sections within the same reference field region into a common region of memory 1023 (e.g., referring to
Furthermore, the topography measurement unit 1007 can be configured to automatically read from these pre-established regions of memory 1023 in order to purposely extract data within a certain reference field and without knowledge of the specific z axis borders themselves. For example, the topography measurement unit 1007 may be pre-configured to: 1) read from a first address (or group of addresses) to obtain the pixel locations of detected fringe lines within a “first” reference field; 2) read from a second address (or group of addresses) to obtain the pixel locations of detected fringe lines within a “second” reference field;, etc, As such, access to the specific z axis border values are not needed by the topography measurement unit according to this perspective.
7.2 Tracking Multiple Fringe Lines within the Same Reference Field
As mentioned previously, memory resources may be partitioned on a reference field by reference basis regardless as to whether or not fringe lines are expected to breach their corresponding reference fields. For example, referring to
However, if fringe line disturbances are expected to breach their corresponding reference fields, more sophisticated signal processing techniques may be necessary. Better said, once fringe line disturbances are allowed to breach their reference fields, different fringe lines may occupy the same reference space. As such, a technique should be used where different fringe lines can be recognized within the same reference field space so that their respective disturbance(s) can be correctly measured. For example, fringe line segment BC of
According to the signal processing technique of
Then, in over the course of executing the second tracking sequence 2001 in an “upward” direction, the technique may (after the reference fields beneath location 1911 and between locations 1911 and 1912 have already been processed): 1) read from a memory the image data corresponding to the reference field between undisturbed fringe line locations 1913 and 1912 and track the upward edge segments “EF” of fringe line 1951b and “JK” of fringe line 1951c; then, 2) read from a memory the image data corresponding to the reference field between undisturbed fringe line locations 1914 and 1913; and, track the upward edge segment “FG” of fringe line 1951b;, etc. Eventually the reference field between fringe line locations 1915 and 1914 will be processed signifying the end of sequence 2002.
Then, starting at its intercept with the upper border of the reference field, each fringe line segment is “tracked” (e.g., by recognizing the existence of proximate pixel locations) while translating it into sample height zs at the proper xy sample stage positions 2102. The tracking and translating 2102 can be viewed as multidimensional 21021 through 2012n where the dimension size depends on the number of different fringe line segments that are to be processed. That is, if one segment requires processing in the downward direction (e.g., as is the case with respect to the reference field between positions 1914 and 1913) n=1; if two segments require processing in the downward direction (e.g., as is the case with respect to the reference field between positions 1913 and 1912) n=2;, etc.
A fringe line segment may be tracked in the downward direction by starting at its intercept with its “upper” border and searching for or otherwise recognizing the existence of (within the reference field data) a proximately located pixel coordinate (e.g., by scanning the data and seizing the closest pixel location that is “down and/or to the right” of the intercept—in simple cases this should correspond to just selecting the pixel location having the next highest x value). The process is then continually repeated until the intercept point with the next lower reference field is reached; or, the fringe line doubles back and recrosses the upper border.
Each pixel location of a fringe line segment may be translated into its appropriate x, y, zs sample topography information through the use of the stored measurement scale information and an understanding of the overall geometry and optics. In an embodiment, consistent with the illustrations provided herein, for any fringe line pixel location (x,z): 1) the appropriate sample stage x coordinate value is determined by factoring the x coordinate of the pixel by a “per pixel resolution in the x and y direction” parameter (e.g., such as that discussed toward the end of section 3.1); 2) the appropriate sample stage y coordinate value is determined by reference to the particular fringe line being tracked (e.g., fringe line 1951b is understood to be y axis location −Y on the sample stage) and, 3) the appropriate sample height zs is determined according to the relationship
zs=REF2+(R−dz)
where: a) REF2 is a “baseline reference” that takes into account how many reference fields the fringe line has already breached; b) R is the “sample height per reference field breach”; and c) dz is the difference between the pixel's z axis detector location and the location of the lower reference field border REF1 (i.e., z-REF1) factored by a per pixel unit of sample height parameter. A more thorough discussion of each of these follows below.
REF2 can be viewed as a variable that is kept track of for each fringe line. That is, in various embodiments, a separate REF2 variable is maintained for each fringe line being tracked. Each time a fringe line breaches another reference field, its corresponding REF2 variable is incremented by N(Δz) where N is the number of pixels (along the z axis of the detector) between neighboring fringe lines and Δz is the per pixel unit of sample height (e.g., as discussed in section 3.2). As such, when a fringe line is within its field of reference (such as fringe line 1951b segment AB) the REF2 variable is 0 has not yet breached its field of reference.
When a fringe line breaches its first field of reference and needs to be tracked across a second field of reference (such as fringe line 1951b segment BC), the fringe line's REF2 variable will be incremented to a value of N(Δz) for the translation process that occurs in the fringe line's second field of reference. Similarly, should the fringe line breach into a third field of reference, the fringe line's REF2 variable will be incremented to a value of 2N(Δz) for the translation process that occurs in the third field of reference, etc. As such, the REF2 variable for a fringe line converts each field of reference breach into a corresponding sample height distance.
Whereas the REF2 variable represents the amount of sample height that has been measured “so far” for a particular fringe line, R (the “sample height per reference field breach”) represents the field of sample height locations that are implicated by the tracking of the fringe line within the field of reference that is currently being processed. As such, R is a fixed value of N(Δz). Here, for any detector z axis location, the term R-dz effectively represents, how far into the current reference field the fringe line has extended. That is, as dz represents the per pixel unit of sample height Δz factored by the distance above REF1 (referring to
When the “downward” sloped fringe lines have been tracked in a reference field, the looping nature of the methodology of
For those fringe lines that do not breach into the next field of reference some form of data compression may be undertaken. For example, in the case of fringe line 1951b when the reference field between locations 1912 and 1911 is being analyzed, the data tracking process may be terminated at point D1 such that only the edges of the sample are actually measured. Alternatively, the tracking process may be slowed down from point D1 to point D2 so that the density of translated sample points is reduced when running across a flat plane of the sample. Either of these techniques reduces the number of pixel locations used for topography information; which, in turn, corresponds to a form of data compression.
After the downward sloped fringe line edges are tracked, a similar process is repeated but in the opposite, upward direction. Here, the methodology of
The most significant difference is that, in one embodiment, the appropriate sample height zs is determined according to the relationship
zs=REF2−dz
where REF2 is the same “baseline reference” that takes into account how many reference fields the fringe line has already breached—but, in the upward direction it is decremented (rather than incremented) by N(Δz) each time a higher reference field is analyzed. Note that the lower border for purposes of determining dz in this case is REF2. Once all the fringe lines have been tracked and the tracking process reaches the highest field of reference, a collection of (x,y,zs) data points are left remaining that describe the topography of the sample in three dimensions. Those of ordinary skill will be able to develop topography measurement unit 1007 software and/or hardware that can perform the techniques described just above.
8.0 Closing Statement
In the foregoing specification, the inventions have been described with reference to specific exemplary embodiments thereof. It will, however, be evident that various modifications and changes may be made thereto without departing from the broader spirit and scope of the invention as set forth in the appended claims. The specification and drawings are, accordingly, to be regarded in an illustrative rather than a restrictive sense.
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